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CHAPTER III
PETROLOGY OF THE GRANITES
Modal Analysis of the Granites
Determination of the mineral composition and the i r re la t ive
proportions in the various types of granit ic rock exposed in the
area were carr ied out to differentiate and classify the granite types
on the basis of thei r mineralogy. K-feldspars in thin sections were
stained using the method suggested by Baily and Stevens (1960) to
differentiate them from untwinned plagioclases. The thin sections
were etched by concentrated hydrofluoric acid and then dipped into
a solution of Sodium Cobalt ini t r i te . As a resul t , the K-feldspars
were stained yellow. Modal compositions of the five types of granite
were determined by the point count method of Chayes (1956). Fifty
thin sections, ten of each type of grnnaite were studied to determine
the modal abundance of the constituent minerals.
The five types of granite have similar mineral composition.
However, differences in tho rolntivo projiorUnn nl various minerals
in the different types of granite can be observed. The range and
average modal composition of the five types of granite are presented
in Table 4.
The variation in the re la t ive proportions of different minerals
in the various types of granite i s evident . The three older granites
a re enriched in ferroniagnesian minerals including biotite and
- 3 0 -
•32-
hornblende and have high content of plaRioclase, whereas K-feldspar
i s re lat ively low. In the younger granites, the content of
ferromagnesian minerals and plagioclase decreases with concomitant
increase in K-feldspar and quartz . The two older granites have a
higher plagioclase : K-feldspar ra t io , whereas the younger granites
have a p lagioclase : K-feldspar ra t io of less than 1. Absence of
hornblende in the younger two leucogranites i s significant.
The modal quartz , potash feldspar and plagioclase (recalculated
to 100%) were plotted on the Orthoclase-Albite-Quartz phase diagram
(Figure 16) of James and Hamilton (1969). Plots of all the five
types of granite are concentrated mainly in the central part of the
diagram. However, the plots of the two older granites , having a
plagioclase : k- fe ldspar ra t io of more than 1, are dis t inct ly res t r ic ted
towards the plagioclase field, whereas the three younger granites
plot towards k-fe ldspar field.
These plots are also res t r ic ted in and around the area of low
temperature trough suggesting that the granites cooled slowly
maintaining ocjuilibrium tlirouglioul llio coolhig.
Modal values of quartz , a lb i te and orthoclase were plotted
on the St reckeisen ' s (1976) classification diagram (Figure 17). The
plots of the hornblende granite extend from the granodiorite to
granite field, whereas the plots of foliated bioti te granite,
porphyr i t i c biot i te granite, coarse grained leucogranite and fine
grained leucogranite are res t r ic ted to the granite f ield.
-33-
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•a c x: X I—I 0 •a G
O
o (—I
a Q) w CO
(—1 u o t-l o
(0 I
N
u CD D
cr
u CO
(D
DO
-35-
Petrography of the Granitic Rocks
Hornblende Granite
On the basis of field re la t ionship , the hornblende granite is
inferred to be the oldest granite in the area. Xenoliths of
hornblende granite are found in all the younger types .
It is a medium grained rock generally showing hypidiomorphic
granular texture , at places, small phenocrysts of plagioclase are
found in the rock. The clusters of ferromagnesian minerals impart
a spotted appearance to the rock.
Plagioclase i s the dominant mineral and constitute about 30.3%
to 43.3% of the rock by volume; the average being 36.7%. The
plagioclase is sodic in composition, ranging from An to An „. Zoning
in plagioclase i s common, the calcic core being re la t ively more
al tered than the rims in the zoned plagioclases (Figure 18).
Antiperthi t ic intergrowth of microclinn is commonly observed In tho
rock; most of the microcline grains within the plagioclase crys ta ls
show similar optical orientation (I'iguro 1!)). Ilio formntion of tlie
ant iper th i te may be at t r ibuted to the growth of microcline on low
energy surfaces of ea l r ier formed plagioclases. Sometimes plagioclase
grains are par t ia l ly enclosed within the biot i te c rys ta ls (Figure
20) which indicates the ear l ier crystal l izat ion of plagioclase.
Myrmekitic intergrowth is ve ry r a r e , a few plagioclase grains show
enclaves of quartz which is believed to be of exsolution origin.
pin ur..". -IS. Zoning in ;olaa;ioGl'ase vith an altered calcic core and a clear nodic rim. 'Jnossed Dolars.
Fi -^ir-c ly. Anti-oerthitic intergrowth of -nicrocline, Most of the microcline f rains shov/ similar onticai orientation. Crossed :)olars
36
Fin-ure 20. ?1 afi'locl ase ( r") b i o t i t p (B) ovYst-^l r .
nRrti-T,] 1 y enclosed vn t h i n Gr-ossed -^lolars.
37
- 3 8 -
Quartz i s also fair ly abundant in the rock, i t has a modal
concentration of 24.8 to 36.5%, with an average of 29.6% by volume.
Quartz occurs in the form of subhedral to anhedral grains, the
contact between the quartz c rys ta l s are highly embayed.
K-feldspar, mainly microcline, i s re la t ive ly less abundant and
constitutes an average of about 20% of the rock by volume.
Untwinned orthoclase c rys ta l s in the rock are very r a r e . Vein
per th i te is also observed which i s inferred to be of exsolutlon
origin.
Biotite and hornblende comprise an average of 6.3% and 3.1%
of the rock, respec t ive ly . Alteration of biot i te to chlori te is
common. Sphene, zircon, apat i te and magnetite are common accessories;
sometimes these minerals occur as inclusions in b io t i te .
Foliated Biotite Granite
The general texture of the rock is hypidiomorphic granular.
The rock sometimes exh ib i t s porphyr i t i c texture with phenocrysts
of microcline set in the matrix of quartz, plagioclase, microcline
and b io t i te . Plagioclase is the dominant mineral in the rock having
mean modal abundance of 37%, quartz comprises 30.9% and K-feldspar
25.2% of the total rock.
Plagioclase in the rock ranges in composition from An to An . 6 16
Normal zoning is also observed in some of the plagioclase c rys ta l s ,
• 3 9 -
the calcic core being intensely al tered to s e r i c i t e . K-feldspars
are re la t ive ly less al tered and are generally per th i t i c in nature.
Several types of pe r th i t e have been reported to occur simultaneously
in per th i t ic microcline (Smith, 1974).
Arinmson (1942) and Smith (1974) ohsorvnd that tho porthltns
from Plutonic rocks show a range of textures which appears to
depend on the bulk chemistry and on the tectonic environment.
Michot (1961) invented the term mesoperthlte for a special type of
microperthi te whose lamellae are so intimately Interrelated that
nei ther phase appears to dominate. Anderson (1966) opined that the
two components of mesoperthlte tend to occur equal ly. Soldatos (1962)
studied microcline pe r th i t e from Yxsjeveberg, Sweden and observed
two generations of micro-albi te , the coarser may be termed as film
per th i t e and the finer one, string pe r th i t e . The various types of
pe r th i t e occuring in the rock are shown in Figures 21 and 22.
Sometimes veins of a lb i te from plagioclase extend into K-feldspar
suggesting Its oxsolutlon origin (P'lgurn 23).
Myrmekitic intergrowth is also observed; i t is
character is t ica l ly res t r ic ted along the contact of K-feldspar and
plagioclase. In a few cases, quartz occurs as elongated band in
K-feldspar. Most of the myrmekites have a covex margin towards
K-feldspar. The vermicules of quartz are uniformly dis t r ibuted and
typical ly thicker at the boundary of plagioclase and become
vnnishingly thinner towards the K-feldspnr boundary (Figure 24).
Qurtz also occurs as i r regular droplets in K-feldspar. The quartz
Fir-UT-e ?1 . iVlesooerthite v/ith i i i t imately i r i ter re la ted lamel lae . Crossed "HOI'^T'S.
Fip:ure //^. Tvo '-venerations of rnicro-albi te , the coarsen one, fil"i oe r th i t e an i the f iner OVIQ ^ strin'-'' oer^-hit',. Gros'^eci oolars .
^i/^ure 23- 7eins of a l b i t e from plar^ioclase e-tend i i t o i:-feli.'3oar (ICf). Jroased i:>olars.
?i"-ure; .;-+. 'lyrmekite interf^rov/th wit i vermiculen -uar tz uniformly d i s t r i b u t e d ±'n Cro3.5ed oolars .
lolagioclase.
- 4 2 -
rods were concluded to be younger than the enclosins plaRlonlaBe
and older than the K-feldspar (Sarma and Raja, 1958, 1959).
Myrmekite occuring at the boundary of K-feldspar in contact with
plagloclase i s concluded to have formed as a result of corrosion
(Drescher-Kaden, 1948). He also opined that the myrmekite may
signify a metasomatic origin. Graphic intergrowth of quartz and
microcllne is also observed in a few samples (Figure 25).
Biotite i s the most dominant accessory mineral and constitute
4.3% of the rock by volume; some c rys ta l s of bioti te are par t ia l ly
al tered to ch lor i te . At places, biot i te encloses apat i te and zircon
grains which may indicate the growth of biot i te c rys ta l s within a
melt (Noyes et a l , 1903). Grains of zircon have well developed
crys ta l faces and are zoned (Figure 26). Zoning of zircon indicates
the evolution of magma by fractional crystal l izat ion process (Martin,
1987).
The deformation of the rock is manifested by the strained
quartz grains and fracturing of plagioclase twin lamellae.
Porphyr i t ic Biotite Granite
The granite is very coarse grained with a porphyr i t ic texture,
the large phenocrysts of microcllne are set in the groundmass
composed of small grains of feldspar, quartz and biot i te .
''ip^ure 25. Grapiiic i n t e r g r o w t h 01 a u a r t z (1) and m i c r o c l i n e ( i l ) . Jrosoed o o i a r s .
^T'. ''»*i I
F1 f;ure 2o. joneu eu . ie i ra l '/.ircon. J ros ^ca 00 L xr .
43
• 44 -
K-feldspar i s the dominant mineral constituting about 39.4% of
the rock by volume. Quartz has a mean modal abundance of 32.7%,
whereas plagioclase, occuring as subordinate to both the K-feldspar
and quartz , forms an average of 24.7% of the rock. Quartz grains
are generally subhedral with embayed outline. Post-crystal l izat ion
deformation of the rock i s indicated by the bending of the biotite
c rys ta l s (Figure 27).
Plagioclase ranges in composition from An to A . Normal 6 11
zoning in plagioclase i s common, the al tered calcic core is mantled
by clear a lb i te r im. Abundance of car lsbad twinning in plagioclases
suggests a mgmatic origin of the grani te . Vermicular intergrowth of
quartz in plagioclase is r a r e .
Microcline occurs both as large phenocrysts and as small grains
in the groundmass; th is may be at t r ibuted to the poly baric
crystal l izat ion of the granit ic magma. Large c rys ta l s of microcline
a re generally pe r th i t i c which i s considered to be of replacement
origin. Veins and str ingers of a lb i te extend from plagioclase into
microcline (Figure 28). It i s inferred that the per th i te forming
solutions have infil trated the K-feldspar along the interleptonic
spaces provided by cracks and cleavages.
Biotite, generally green in colour, constitutes about 2.7% of
the rock by volume. The accessory minerals include apat i te , sphene,
epidote and zircon.
Pigure 27. P o s t - c r j s t a l l i z a t l o n defornation of the rock 'Tianifested by the bending of b i o t l t e (3) c rys ta l s . Crossed t)olars.
Fi<n;ure 28. Veins and s t r in i jers of a i o i t e extend from plagiocla^e { i^) i n to -nicrocline (.1). Crossed oolars,
45
- 4 ( 5 -
Coarse Grained Leucogranite
It Is n rnodium to conrsG Rralnorl rnoRsivo rnck cornposod mainly
of potash feldspar and quartz which constitute an average of 37.2%
nnri Sfi.lli of tho rock hy volninR, rnRpnnllvnly. Mnjorlty of Ihn
microcline grains are per th i t i c in nature. The per th i tes are of
var iab le type and are inferred to have formed by replacement as
well as exsolution processes . Myrmekitlc intergrowth, generally
res t r ic ted at the microcline-plagioclase contact (Figure 29), suggests
an exsolution origin of the myrmekite (Hubbard, 1966, 1967). Quartz
also occurs as inclusion in plagioclase and microcline.
Plagioclase is subordinate to both K-feldspar and quartz and
constitutes an average of 23.1% of the rock; the grains are generally
weathered to se r i c i t e . Plagioclase composition ranges from An to o
An . Inclusion of plagioclase c rys ta l s within K-feldspar suggest
ear l ie r crystal l izat ion of plagioclase. Normal zoning and Carlsbad twinning in plagioclases suggest a magmatic origin of the granite.
Biotite is the major ferromagnesian mineral, it constitutes about
1.9% of the rock. Hornblende, in contrast to older types, is
conspicuously absent. Zircon c rys ta l s are generally euhedral in shape.
The presence of zoned crys ta l s of zircon (Figure 30) suggests
evolution of magma through fractional crystal l izat ion process (Martin,
1987). Sphene, epidote and apat i tes are common accessories.
i^'if^ure -^q. ly rnek i t e in tergro^vth r e n t r i c t e i i flt t i p n icrocl 3 i^-'-^larioclaTG c o n t n c t . Cros^spi l o l a r g .
^i^nirp 31. juae I'^ai "one i i r c o i . ^ m ^a JO i r (~i -pe*
47
• 4 B -
Flne Grained Leucogranlte
The fine grained leucogranite i s the youngest granite in the
area; i t is observed to have intruded into all the older types of
granite. The rock is massive having hypidiomorphic granular texture
and shows s imilar i ty with foliated biot i te granite . However, it is
finer grained and has lower content of ferromagnesian minerals.
The granite i s composed mainly of quartz and microcline which
constitutes an average of 37.6% and 34.5% of the rock by volume,
respec t ive ly . Plagioclase is subordinate in amount to both quartz and
potash feldspar . Microcline i s generally per th i t ic with veins of
a lbi tes d is t r ibuted uniformly throughout the grain. The textures
of per th i tes suggest i t s origin by exsolution as well as replacement
processes.
Plagioclase ranges in composition from An to An , some
plagioclase c rys ta l s show normal zoning having a relatively more altered
calcic core (Figure 31). Myrmekitic intergrowth is common; in some
cases quartz blebs are observed to exlond from [)lagioclase across
the contact into microcline (Figure 32). Stress may have been
responsible for promoting exsolution and migration of exsolved quartz
to grain boundaries. Smith (1974) opined that the stress
accompanying rock deformation provide channels for migration of
solutions, par t ly by generating regions of usually high and unusually
low pressure which favour appropr ia te material .
Pi;jure 31 . i^lagioclase CrosKei Dolar.i.
crystal vixth normal zonlnp-.
i i. iire 32. Myrmekite inte-i"p;rov;th with bleb of quartz e::tending fro i ola; ;iocla'3e ( ) across t'le contact into 'nicrocline ( i). Crossed oolars.
-50 -
Biotite i s the only major ferromagnesian constituent of the rock,
the average modal value beln.q 2.2\. Similar to coarse grained
leucogranite, hornblende is significantly not found in the rock,
Sphene, zircon, and apat i te a re very r a r e , whereas the opaques are
commonly dis t r ibuted throughout the rock. Garnet and muscovite
i s observed only In one sample. The granite shows l i t t l e effect
of deformation.
An-Content of Plagioclase
The plagioclase composition i s a very significant indicator of
the physico-chemical condition of rock formation. Barth (1969)
suggested that plagioclase of low pressure- temperature formation is
nearly pure a lb i te but plagioclase of higher pressure-temperature
var ies in the composition. Kuno (1956) opined that at high
temperature a lb i te i s always contaminated with appreciable amount
of anorthlte in solid solution.
The composition of plagioclase in 50 samples, 10 of each of
the five types of granite, was determined by the Rittman method
(Emmons, 1943). The result is presented in Table 5.
-51-
Table 5 : Plagioclase composition in the five types of granite.
Rock Type An-content
Hornblende granite
Foliated bioti te granite
porphyr i t i c bioti te granite
Coarse grained leucogranite
Fine grained leucogranite
Ang -
An^ -
An^ -
An^ -
An^ -
• ^ " l 8
• ^ 1 6
• ^ " u
- % 4
• ^ " l 6
It i s evident from Table 5 that there is not much
difference in the An-content of plagioclases among the five types
of granite; the plagioclase is generally sodic in composition.
Hornblende granite, however, has s l ight ly more calcic plagioclases
than the other types .
plagioclase TwinninR
The nature and type of twinning in plagioclase provides
important clues about the origin of the rock; the nature of
plagioclase twinning in igneous rocks differs from the twinning in
metamorphic plagioclases (Gorai, 1951; Vance, 1961; Tobi, 1962;
Seifert, 1964).
-52 -
Goral (1951) observed B charac ter i s t ic difference in the type
of plagioclase twin in magmatic and metamorphic rocks . He classified
the plagioclase twinning into two types , A-type and C-type. A-type
twinning is found both in igneous and metamorphic rocks; it Includes
lamellar a lb i t e , acline and pericl ine twins, alone or in combination.
Secondary glide twins formed due to deformation by external forces
after the growth of the crys ta l are also grouped in A-type twins.
The C-type twins include Carlsbad, a lbi te-Car lsbad and penetration
twins which are developed in the crys ta l during growth and is
res t r ic ted in the magmatic rocks . Abundance of C-type Carlsbad
twinning In plagioclases- in all the five types of Bundelkhand granite
may indicate the i r magmatic origin. A similar conclusion was also
drawn by Alam (1979).
Zoning in Plagioclase
The plagioclase c rys ta l s in al l the five types of Bundelkhand
granite are zoned; the calcic core being Intensely al tered to ser ic i te .
The presence of zoning in the plagioclase grains may suggest a
magmatic origin of the grani tes . Normal zoning in plagioclases (sodic
shel l s around calcic cores) Indicates a magmatic origin. In a
magmatic system as crystal l izat ion proceeds, a ser ies of compositional
changes is induced by regularly decreasing temperature. At the
ini t ial high temperature, calcic plagioclase is in equilibrium with
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